N Bit Adder and Corresponding Adding Method

ABSTRACT

An n bit adder includes first computing circuit with 2n inputs for receiving n values of bits of first and second binary numbers and an additional input for receiving an input carry digit. The first computing circuit elaborates from each of the n pairs of bit values of the same significance, a carry digit propagating signal and diagonal generation signals. The adder further including: an estimating circuit performing a first estimation of each coefficient of the number resulting from the sum of the first and second numbers, by using the complement of the corresponding bit of significance of the first number; a second computing circuit, elaborating a set of correcting signals based on the propagating signals and the diagonal generation signals; a correcting block applying to each estimated value of bit of significance k of the sum, k+1 corrections using the correcting signals, and delivering n bits of the sum.

CROSS-REFERENCE TO RELATED APPLICATIONS

This application is a Section 371 National Stage Application of International Application No. PCT/FR2006/002045, filed Sep. 6, 2006, and published as WO 2007/031622A1 on Mar. 22, 2007, not in English.

FIELD OF THE DISCLOSURE

The disclosure concerns adders and particularly adders of the Carry-Look-Ahead adder (CLA) type, or adders of the carry propagation type (“Ripple Carry Adder”).

BACKGROUND OF THE DISCLOSURE

Conventionally, in order to make an addition between two binary numbers, a standard adder calculates each bit of the resulting sum from the bits of the same rank of each binary input number, and of a carry propagated by the addition of the bits of lower rank.

In other words, these standard adders effect the sum of the two bits of the rank in question of the two binary input numbers, and then make a positive correction if necessary using the propagated carry.

For example, the patents U.S. Pat. Nos. 6,175,852 and 5,636,156 (IBM) present this type of adder.

The patent U.S. Pat. No. 6,578,063 (IBM) also presents a standard adder but with five input binary numbers.

The patent U.S. Pat. No. 5,719,803 (Hewlett Packard Company) keeps the structure of a standard adder while affording an improvement based on Ling's equations.

One of the drawbacks of this type of adder concerns the testability of the logic gates of the adder. This is because, so as to check the behaviour of the gates, it is necessary to use a set of vector tests in order to detect any error in behaviour of the adder. In the case of these standard adders, the number of vectors in this set of tests may be extremely high.

The article “On the Adders with Minimum Tests” by Seiji Kajihara and Tsutomu Sasao proposes to improve the testability of these standard adders by modifying certain gates but without changing the general structure of the adder.

SUMMARY

According to a first aspect of the invention, an n-bit adder of first and second binary numbers, comprising a first calculation means with two n inputs for receiving the n values of bits of said first and second binary numbers and an additional input for receiving an input carry. Said first calculation means is able to produce, from each of the n pairs of values of bits of the same rank, a carry propagation signal.

According to a general characteristic of this first aspect of the invention, the first calculation means is able also to produce n diagonal-generation signals, each diagonal-generation signal being produced from the value of the bit of rank k of the second number, k varying between 0 and n−1, and the value of the bit of rank k−1 of the first number or of the input carry if said coefficient of rank k−1 does not exist. The adder also comprises:

-   -   an estimation means able to perform a first estimation of each         coefficient of the number resulting from the sum of the first         and second numbers, taking the complementary of the value of the         bit of corresponding rank of the first number,     -   a second calculation means connected to the first calculation         means and able to produce a set of correction signals from the         propagation signals and diagonal-generation signals,     -   a correction block comprising n outputs and able to apply, to         each estimated bit value of rank k of said sum, k+1 corrections         by means of said correction signals, and to deliver as an output         the n bits of the sum of the first and second numbers.

In other words, after a first estimation of the final result, the adder performs n successive corrections that may be positive, negative or zero. These corrections are made not only by means of the bits of the input numbers and input carry, but also by means of the bit of preceding rank of the first binary number, by means of the diagonal-generation signals.

The adder allows a novel implementation that has in particular the advantage of improving its testability compared with a standard adder. Indeed, simulations in Verilog language demonstrated for example that 9 test vectors suffice for testing a 4-bit adder.

According to one embodiment, the estimation means is able also to perform a first estimation of a carry resulting from said sum of first and second numbers, from the most significant bit of the first number.

The second calculation means can also produce a set of supplementary signals for correcting said resultant, from the propagation signals and the diagonal-generation signals.

The correction block may also comprise a supplementary output for delivering said resulting carry, and is able to apply, to the estimated bit value of the resulting carry, k+1 corrections by means of said supplementary correction signals.

Preferably, the diagonal generation signal of rank k is estimated according to the following expression:

q_(k)= (b_(k)⊕a_(k-1))

where:

-   -   q_(k) is the diagonal-generation signal of rank k,     -   b_(k) is the bit of rank k of the second binary number.     -   a_(k-1) is the bit of rank k−1 of the first binary number.

Preferably, the p^(th) correction signal of the bit of rank k, with p varying between 0 and k, is determined according to the following expression:

${C_{k}^{p} = q_{k}},{\mspace{11mu} \;}{{{if}\mspace{14mu} p} = 0},{C_{k}^{p} = {{\left\lbrack {\prod\limits_{i = 1}^{p}\; t_{k - i}} \right\rbrack \cdot q_{k - p}}\mspace{14mu} {otherwise}}},$

where:

-   -   C_(k) ^(p) is the p^(th) correction signal of the bit of rank k         of the resulting sum,     -   t_(i) is the carry propagation signal produced from the bits of         rank i of the first and second binary numbers,     -   q_(k) is the diagonal-generation signal of rank k.

Preferably, the bit of rank k of the resulting sum is determined according to the following expression:

${s_{k} = {{\overset{\_}{a}}_{k} \oplus {\sum\limits_{i = 0}^{k}\; C_{k}^{i}}}},$

where:

-   -   s_(k) is the bit of rank k of the resulting sum,     -   a_(k) is the bit of rank k of the first binary number,     -   C_(k) ^(i) is the i^(th) correction signal of the bit of rank k         of the resulting sum.

According to one embodiment, the first calculation means comprises n pairs of “EXCLUSIVE OR” and “EXCLUSIVE OR complement” gates such that, for the k^(th) pair, the “EXCLUSIVE OR complement” gate is able to receive as an input the bit of rank k of the second binary number and bit of rank k−1 of the first binary number or the input carry is said bit of the first binary number of rank k−1 does not exist, and able to deliver as an output the corresponding diagonal-generation signal, and such that, for said k^(th) pair, the “EXCLUSIVE OR” gate is able to receive the bits of rank k of the first and second binary numbers and is able to deliver the carry propagation signal of corresponding rank.

According to one embodiment, the second calculation means comprises, for producing each correction signal for the bit of rank k, k “AND” gates, the i^(th) gate being able to produce a correction signal from the carry propagation and carry generation signals delivered as an input to said “AND” gates.

According to one embodiment, the correction block comprises, for producing the bit of rank k of the resulting sum k+1, “EXCLUSIVE OR” gates connected in series, each gate being able to:

-   -   receive the estimated bit of rank k or the bit of rank k         delivered by the “EXCLUSIVE OR” gate connected upstream, and a         correction signal,     -   perform a correction to the signal received as an input from         said correction signal received.

Moreover, according to another aspect of the invention, there is proposed a system of adding j bits such that j is greater than 2, comprising j−1 adders as described above and connected in series, each adder being able to receive as an input a first binary number and a second binary number corresponding to the sum of two other binary numbers, which is delivered by the adder connected upstream.

According to another aspect of the invention, there is also proposed a system of adding j bits, such that j is greater than 2, comprising a set of adders as described above connected in parallel, in which said second calculation means of each adder:

-   -   also comprises an output able to deliver a group propagation         signal corresponding to the product of all the carry propagation         signals, produced by said first calculation means,     -   is able to produce said set of supplementary correction signals         for said resulting carry, from the propagation signals and the         diagonal-generation signals, as well as the complementary signal         of the first bit of the second input binary number.

The system can also comprise at least one group propagation module connected to all the adders and able to receive said resulting carry and said group propagation signal produced by each adder and to produce firstly the input carry of an adder from the resulting carry and the group propagation signal of the previous adder, and secondly a new resulting carry and a new group propagation signal from the resulting carries and the group propagation signals of all the adders.

According to one embodiment of this third aspect of the invention, the system comprises a first set of propagation modules connected in parallel to the output of the adders, and another propagation module, connected to the output of said first set of propagation modules, able to receive the new resulting carry and the new group propagation signal of each propagation module of said first set, and able to produce, from each new resulting carry and each new group propagation signal, a new output carry and a new output group propagation signal.

According to another aspect of the invention, there is proposed a method of adding first and second n-bit binary numbers, comprising a phase of receiving the n values of bits of said first and second binary numbers and of an input carry, and a first calculation phase comprising the production, from each of the n pairs of values of bits of the same rank, of a carry propagation signal.

According to a general characteristic of this other aspect of the invention, the first calculation phase also comprises the production of n diagonal-generation signals, each diagonal-generation signal being produced from the value of the bit of rank k of the second number, k varying between 0 and n−1, and the value of the bit of rank k−1 of the first number or of the carry if said coefficient of rank k−1 does not exist. The method also comprises:

-   -   a phase of estimating each coefficient of the resulting number         of the sum of the first and second numbers, taking the         complementary of the value of the bit of corresponding rank of         the first number,     -   a second calculation phase comprising the production of a set of         correction signals from the propagation signals and         diagonal-generation signals,     -   a correction phase comprising the application, to each estimated         bit value of rank k of said sum, of k+1 corrections by means of         said correction signals, and the delivery as an output of the n         bits of the sum of the first and second numbers.

According to one embodiment, the estimation phase also comprises a first estimation of a carry resulting from said sum of the first and second number, from the most significant bit of the first number.

The second calculation phase can also comprise the production of a set of supplementary correction signals for said resulting carry, from the propagation signals and diagonal-generation signals.

The correction phase can also comprise the delivery of said resulting carry, and the application, to the estimated bit value of the resulting carry, k+1 corrections using said supplementary correction signals.

Preferably, the diagonal-generation signal of rank k is determined according to the following expression:

q_(k)= (b_(k)⊕a_(k-1))

where:

-   -   q_(k) is the diagonal-generation signal of rank k,     -   b_(k) is the bit of rank k of the second binary number.     -   a_(k-1) is the bit of rank k−1 of the first binary number.

Preferably, the p^(th) correction signal of the bit of rank k, with p varying between 0 and k, is determined according to the following expression:

${C_{k}^{p} = q_{k}},{\mspace{11mu} \;}{{{if}\mspace{14mu} p} = 0},{C_{k}^{p} = {{\left\lbrack {\prod\limits_{i = 1}^{p}\; t_{k - i}} \right\rbrack \cdot q_{k - p}}\mspace{14mu} {otherwise}}},$

where:

-   -   C_(k) ^(p) is the p^(th) correction signal for the bit of rank k         of the resulting sum,     -   t_(i) is the carry propagation signal produced from the bits of         rank i of the first and second binary numbers,     -   q_(k) is the diagonal-generation signal of rank k.

Preferably, the bit of rank k of the resulting sum is determined according to the following expression:

${s_{k} = {{\overset{\_}{a}}_{k} \oplus {\sum\limits_{i = 0}^{k}\; C_{k}^{i}}}},$

where:

-   -   s_(k) is the bit of rank k of the resulting sum,     -   a_(k) is the bit of rank k of the first binary number,     -   C_(k) ^(i) is the i correction signal of the bit of rank k of         the resulting sum.

According to one embodiment, the first calculation phase comprises n pairs of “EXCLUSIVE OR” and “EXCLUSIVE OR complement” operations such that, for the k^(th) pair of operations, the “EXCLUSIVE OR complement” operation comprises the reception as an input of the bit of rank k of the second binary number and of the bit of rank k−1 of the first binary number or of the carry if said bit of rank k−1 of the first binary number does not exist, and comprises the delivery as an output of the corresponding diagonal-generation signal, and such that, for said k^(th) pair of operations, the “EXCLUSIVE OR” operation comprises the reception of the bits of rank k of the first and second binary numbers and the delivery of the carry propagation signal of corresponding rank.

According to one embodiment, the second calculation phase comprises, for the production of each correction signal of the bit of rank k, k “AND” operations, the i^(th) operation comprising the production of the correction signal from the carry generation and carry propagation signals.

According to one embodiment, the correction phase preferably comprises, for producing the bit of rank k of the resulting sum, k+1, “EXCLUSIVE OR” operations in series, comprising the reception of the estimated bit of rank k or of the bit of rank k processed during the previous “EXCLUSIVE OR” operation of the correction phase, and a correction signal, each “EXCLUSIVE OR” operation comprising the correction of the signal received as an input, from said correction signal.

BRIEF DESCRIPTION OF THE DRAWINGS

Other advantages and characteristics will emerge from an examination of the detailed description of a method and in no way limitative embodiments of the invention, and of the accompanying drawings, in which:

FIG. 1 depicts schematically a first embodiment of an adder according to an embodiment of the invention,

FIG. 2 depicts an embodiment of the method according to an embodiment of the invention,

FIG. 3 depicts more precisely an embodiment of an adder according to an embodiment of the invention,

FIG. 4 depicts a system comprising several adders according to an embodiment of the invention,

FIG. 5 depicts another system comprising several adders according to an embodiment of the invention,

FIG. 6 depicts more precisely an adder included for example in the system shown in FIG. 5,

FIG. 7 shows another system comprising several adders according to an embodiment of the invention.

DETAILED DESCRIPTION OF ILLUSTRATIVE EMBODIMENTS

FIG. 1 depicts an integrated circuit CI. The reference ADD represents an adder according to an embodiment of the invention. In comprises a first calculation means MCI able to receive two binary numbers A and B such that:

A=a ₃·2³ +a ₂·2² +a ₁·2+a ₀

B=b ₃·2³ +b ₂·2² +b ₁·2+b ₀

In this example, the first binary numbers A and B comprise four bits but the example applies more generally to any n-bit binary number. In addition, in this example, A is considered to be the first binary number and B to be the second binary number, but their role can of course be interchanged.

The first calculation means MC1 comprises here a first input for the input carry z_(in) and four pairs of inputs for the four bits of the first and second binary number, respectively a₀ and b₀, a₁ and b₁, a₂ and b₂ and a₃ and b₃.

From these input bits, the first calculation means MC1 produces two types of signal: carry propagation signals t_(n) and diagonal-generation signals q_(n). The carry propagation signals t_(n) and the diagonal-generation signals q_(n) can be expressed in the form:

$\left\{ {{\begin{matrix} {t_{n} = {b_{n} \oplus a_{n}}} \\ {q_{n} = \overset{\_}{\left( {b_{n} \oplus a_{n - 1}} \right)}} \end{matrix}\mspace{14mu} {and}\mspace{14mu} q_{0}} = \overset{\_}{b_{0} \oplus z_{i\; n}}} \right.$

The diagonal-generation signals were produced by the inventor by virtue in particular of a new expression of the bits of the resulting sum of the first and second input binary numbers of the adder and of the carry resulting from this same addition.

This is because, starting from an expression of the resulting carry z_(n) and the bits of the sum s_(n):

$\left\{ \begin{matrix} {z_{n} = {g_{n - 1} + {p_{n - 1} \cdot z_{n - 1}}}} \\ {s_{n} = {t_{n} \oplus z_{n}}} \end{matrix}\quad \right.$

and signals generating a carry in n, g_(n), signals propagating or generating a carry in n, p_(n) and signals propagating a carry in n without generation t_(n), used by a standard adder, such that:

$\left\{ \begin{matrix} {g_{n} = {a_{n} \cdot b_{n}}} \\ {p_{n} = {a_{n} + b_{n}}} \\ {t_{n} = {a_{n} \oplus b_{n}}} \end{matrix}\quad \right.$

the inventor established that the carry produced from each rank is expressed according to the following formula:

Z _(n) =a _(n-1) ⊕t _(n-1) ·q _(n-1) ⊕t _(n-1) ·t _(n-2) ·q _(n-2) ⊕t _(n-1) ·t _(n-2) ·t _(n-3) ·q _(n-3) ⊕ . . . ⊕t _(n-1) ·t _(n-2) . . . t ₁ ·t ₀ ·q ₀

where:

q_(n) is the diagonal-generation signal according to the formula established above.

This, for the two binary numbers A and B cited previously, there comes:

$\left\{ \begin{matrix} {z_{1} = {a_{0} \oplus {t_{0} \cdot q_{0}}}} \\ {z_{2} = {a_{1} \oplus {t_{1} \cdot q_{1}} \oplus {t_{1} \cdot t_{0} \cdot q_{0}}}} \\ {z_{3} = {a_{2} \oplus {t_{2} \cdot q_{2}} \oplus {t_{2} \cdot t_{1} \cdot q_{1}} \oplus {t_{2} \cdot t_{1} \cdot t_{0} \cdot q_{0}}}} \\ {z_{4} = {a_{3} \oplus {t_{3} \cdot q_{3}} \oplus {t_{3} \cdot t_{2} \cdot q_{2}} \oplus {t_{3} \cdot t_{2} \cdot t_{1} \cdot q_{1}} \oplus {t_{3} \cdot t_{2} \cdot t_{1} \cdot t_{0} \cdot q_{0}}}} \end{matrix}\quad \right.$

Consequently, by substituting Z_(n) in:

S_(n)=t_(n)⊕Z_(n)=a_(n)⊕b_(n)⊕Z_(n)

there is obtained:

$\left\{ \begin{matrix} {s_{1} = {\overset{\_}{a_{1}} \oplus q_{1} \oplus {t_{0} \cdot q_{0}}}} \\ {s_{2} = {\overset{\_}{a_{2}} \oplus q_{2} \oplus {t_{1} \cdot q_{1}} \oplus {t_{1} \cdot t_{0} \cdot q_{0}}}} \\ {s_{3} = {\overset{\_}{a_{3}} \oplus q_{3} \oplus {t_{2} \cdot q_{2}} \oplus {t_{2} \cdot t_{1} \cdot q_{1}} \oplus {t_{2} \cdot t_{1} \cdot t_{0} \cdot q_{0}}}} \end{matrix}\quad \right.$ and S₀ = t₀ ⊕ z_(i n)

This new expression of the resulting carry at rank n, z_(n), is obtained first of all by expressing it as a function of the carry propagation signal t_(n-1), to rank n−1. As z_(n)=g_(n1)+p_(n-1)·z_(−n1), there then comes, according to the conventional combinatorial logic rules:

z _(n) =g _(n-1) +p _(n-1) ·z _(n-1)

z _(n) =a _(n-1) ·b _(n-1)+(a _(n-1) +b _(n-1))·z _(n-1)

z _(n) =a _(n-1) ·b _(n-1)+(a _(n-1) ⊕b _(n-1) ⊕a _(n-1) ·b _(n-1))·z _(n-1)

z _(n) =a _(n-1) ·b _(n-1) +a _(n-1) ·b _(n-1) ·z _(n-1)+(a _(n-1) ⊕b _(n-1))·z _(n-1)

z _(n) =a _(n-1) ·b _(n-1)(1+z _(n-1))+(a _(n-1) ⊕b _(n-1))·z _(n-1)

z _(n) =a _(n-1) ·b _(n-1)+(a _(n-1) ⊕b _(n-1))·z _(n-1)

z _(n) =a _(n-1) ·b _(n-1)⊕(a _(n-1) ⊕b _(n-1))·z _(n-1) ⊕a _(n-1) ·b _(n-1)·(a _(n-1) ⊕b _(n-1))·z _(n-1)

z _(n) =a _(n-1) ·b _(n-1)⊕(a _(n-1) ⊕b _(n-1))·z _(n-1)

z _(n) =g _(n-1) ⊕t _(n-1) ·z _(n-1)

By expressing the generation signal of a carry g_(n-1) to rank n−1 as a function of the propagation signal of a carry t_(n-1) to rank n−1 without generation, there comes:

g _(n-1) =a _(n-1) ·b _(n-1)

g _(n-1) =a _(n-1)·(1⊕ b _(n-1) )

g _(n-1) =a _(n-1) ⊕a _(n-1)· b _(n-1)

g _(n-1) =a _(n-1)⊕ b _(n-1) ·(a _(n-1) ⊕b _(n-1))

g _(n-1) =a _(n-1)⊕ b _(n-1) ·t _(n-1)

Consequently, by replacing the value of g_(n-1) in the last expression of z_(n) above, there comes:

z _(n) =a _(n-1)⊕ b _(n-1) ·t _(n-1) ⊕z _(n-1) ·t _(n-1)

or

z _(n) =a _(n-1) ⊕t _(n-1)·( b _(n-1) ⊕z _(n-1))

Consequently, in the light of the above, by replacing z_(n-1) by

a_(n-2)⊕t_(n-2)·( b_(n-2) ⊕Z_(n-2)), (obtained by recurrence) there comes:

z _(n) =a _(n-1) ⊕t _(n-1)·( b _(n-1) ⊕a _(n-2) ⊕t _(n-2)·( b _(n-2) ⊕Z _(n-2)))

q_(n) being defined by: q_(n)= b_(n)⊕a_(n-1) and

therefore qn−1 by: q_(n-1)= b_(n)⊕a_(n-2) : there comes:

z _(n) =a _(n-1) ⊕t _(n-1)(q _(n-1) ⊕t _(n-2)·(b _(n-2) ⊕Z _(n-2)))

By replacing the term z_(n-1) by expressions obtained by recurrence, the formula of z_(n) mentioned above is obtained,

The first calculation block MC1 therefore delivers the carry propagation and diagonal-generation signals of rank 0 to 3, respectively q₀ and t₀, q₁ and t₁, q₂ and t₂ and q₃ and t₃.

The adder ADD also comprises an estimation means MEST that receives as an input the bits of the first binary number A, that is to say a₀, a₁, a₂ and a₃.

From these various inputs, the estimation means MEST estimates the bits of the sum s_(n) of the two binary numbers A and B.

In other words, the bits s_(n) of the of the sum S of the numbers A and B will firstly be estimated as being equal to the complementary of the bits of the first binary number A, that is to say a₀,a₁,a₂ and a₃ .

Moreover, the adder ADD comprises a second calculation means MC2 connected to the first calculation means MC1.

The first calculation means MC1 then delivers the various carry propagation and diagonal-generation signals q₀, t₀, . . . q₃, t₃ to the second calculation means MC2.

From these various input signals, the second calculation means MC2 produces correction signals that are applied to the various estimations of the bits of the resulting sum of A and B delivered by the estimation means MEST.

The various correction signals C₀ ⁰, C₁ ⁰, C₁ ¹, C₂ ⁰, . . . C₂ ², C₃ ⁰, . . . C₃ ³ are calculated from the following formula:

$\left\{ \begin{matrix} {C_{0}^{0} = q_{0}} \\ {{C_{1}^{0} = q_{1}},{C_{1}^{1} = {t_{0} \cdot q_{0}}}} \\ {{C_{2}^{0} = q_{2}},{C_{2}^{1} = {t_{1} \cdot q_{1}}},{C_{2}^{2} = {t_{1} \cdot t_{0} \cdot q_{0}}}} \\ {{C_{3}^{0} = q_{3}},{C_{3}^{1} = {t_{2} \cdot q_{2}}},{C_{3}^{2} = {t_{2} \cdot t_{1} \cdot q_{1}}},{C_{3}^{3} = {t_{2} \cdot t_{1} \cdot t_{0} \cdot q_{0}}}} \end{matrix}\quad \right.$

The second calculation means MC2 delivers the correction signals to various correction means, mcorr1, . . . mcorr14.

The correction signal C₀ ⁰ is applied to the first estimation of the first bit of the sum s₀ ⁰, that is to say a₀ . This correction makes it possible to obtain the definitive bit of rank O of the sum S, that is to say s₀.

The first estimation s₁ ⁰ of the second bit of the sum s₁, is corrected on the first occasion by means of the block mcorr2, which receives the correction signal C₁ ⁰. The correction block mcorr2 then delivers a second estimation s₁ ¹ of the bit s₁ of the sum of the numbers A and B. This second estimation s₁ ¹ is delivered to the correction block mcorr3, which also receives the correction signal C₁ ¹. The correction block mcorr3 then delivers the bit s₁ of the sum S.

Likewise, the first estimation s₂ ⁰ of the third bit s₂ of the sum S is corrected successively by the correction blocks mcorr4, mcorr5 and mcorr6, which receive respectively the correction signals C₂ ⁰, C₂ ¹ and C₂ ².

Likewise, the third estimation s₃ ⁰ of the fourth bit s₃ of the sum S is corrected successively by the four correction blocks mcorr7, mcorr8, mcorr9 and mcorr10, which receive respectively the correction signals C₃ ⁰, C₃ ¹, C₃ ² and C₃ ³.

The adder ADD comprises an additional output for delivering a carry z₄ corresponding to the carry of the sum of the two numbers A and B.

This supplementary output may not exist, for example in the case of an adder used for carrying out a circular addressing on 16 values, used in particular in digital filtering of a signal for addressing the 16 coefficients of the filter or for calculating the fast Fourrier transformation.

Just as for the various coefficients s₀ . . . s₃ of the sum S, the resulting carry z₄ is estimated by the estimation means MEST. At the end of the first estimation, the carry z₄ ⁰ is equal to the most significant bit of the first binary number, that is to say a₃.

This first estimation is corrected by means of four correction blocks mcorr11, mcorr12, mcorr13 and mcorr14, which received respectively the correction signals C₄ ⁰, . . . , C₄ ³.

These correction signals are delivered by the second calculation means MC2 and are produced from the following formula:

C ₄ ⁰ =t′ ₃ ·q ₃ , C ₄ ¹ =t ₃ t ₂ q ₂ , C ₄ ² =t ₃ ·t ₂ ·t ₁ ·q ₁ , C ₄ ³ =t ₃ ·t ₂ ·t ₁ ·t ₀ ·q ₀.

Finally, the bits of the sum S and the resulting carry z₄ are obtained by the formulae:

$\left\{ \begin{matrix} {S_{0} = {S_{0}^{0} \oplus C_{0}^{0}}} \\ {S_{1} = {S_{1}^{0} \oplus C_{1}^{0} \oplus C_{1}^{1}}} \\ {S_{2} = {S_{2}^{0} \oplus C_{2}^{0} \oplus C_{2}^{1} \oplus C_{2}^{2}}} \\ {S_{3} = {S_{3}^{0} \oplus C_{3}^{0} \oplus C_{3}^{1} \oplus C_{3}^{2} \oplus C_{3}^{3}}} \end{matrix}\quad \right.$ and Z₄ = a₃ ⊕ C₄⁰ ⊕ C₄¹ ⊕ C₄² ⊕ C₄³

Reference is now made to FIG. 2, which illustrates an example of a method used by an adder according to an embodiment of the invention.

During a first step 10, the adder receives the bits of the two numbers to be added, respectively A and B, and an input carry z_(in).

During step 11, a first estimation of the resulting sum S of the binary numbers A and B is made from the bits of the first binary number A.

During a step 12, the carry propagation signals and diagonal-generation signals, respectively t₀, . . . , t₃ and q₀, . . . q₃, are produced from the bits of the input binary numbers A and B.

During a step 13, various correction signals C_(n) ^(k) are produced from the carry propagation and diagonal-generation signals.

During a step 14, these various correction signals are applied to the first estimations of the bits of the sum S and of the resulting carry so as to obtain the bits s₀, s₁, s₂ and s₃ of the sum and the resulting carry z₄.

A first example of this method is given in the following table with A=0101 as the first binary number (line 1 of the table), B=0011 as the second binary number (line 2) and z_(in)=0 as the input carry.

Index n 3 2 1 0 Z_(in) A 0 1 0 1 0 B 0 0 1 1 t_(n) = a_(n) ⊕ b_(n) 0 1 1 0 q_(n) = b_(n) ⊕ a_(n−1) 0 1 1 0 s_(n) ⁰ = a_(n) 1 0 1 0 C_(n) ⁰ = q_(n) 0 1 1 0 s_(n) ¹ = C_(n) ⁰ ⊕ s_(n) ⁰ 1 1 0 0 C_(n) ¹ = t_(n−1) · q_(n−1) 1 1 0 s_(n) ² = C_(n) ¹ ⊕ s_(n) ¹ 0 0 0 0 C_(n) ² = t_(n−1) · t_(n−2) · q_(n−2) 1 0 s_(n) ³ = C_(n) ² ⊕ s_(n) ² 1 0 0 0 C_(n) ³ = t_(n−1) · t_(n−2) · t_(n−3) · q_(n−3) 0 S = C_(n) ³ ⊕ s_(n) ³ 1 0 0 0

During a first step, the signals t_(n) and q_(n) as defined above are calculated. Then t_(n)=0110 (line 3) and q_(n)=0110 (line 4). A first estimation of each bit of the resulting sum (line 5) is next made and then the first correction signals to be applied to each estimated bit value are calculated (line 6).

Then a second estimation of the bits of the sum is derived therefrom, that is to say s₀ ¹, s₁ ¹, s₂ ¹ and s₃ ¹ (line 7).

The second correction signals of the second estimated values of the bits of the resulting sum are calculated (line 8).

The bits of the resulting sum are corrected a second time so as to obtain s₃ ² and s₂ ² (line 9).

The correction signals to be applied to the estimated bits s₃ ² and s₂ ² are calculated according to the formula set out in the table (line 10), and the estimated bit s₃ ³ (line 11) is derived therefrom.

Finally, the last correction signal is calculated according to the formula set out in the table so as to obtain the final sum S, which is here equal to 1000 (line 12).

The initial expression of the sum being 1010 and the final expression being 1000, the corrections have in this example had a negative effect. Moreover, the emerging carry is zero. This is because with:

Z₄=a₃⊕C₄ ⁰⊕C₄ ¹⊕C₄ ²⊕C₄ ³=0,

with:

C ₄ ⁰ =t ₃ ·q ₃=0, C ₄ ¹ =t ₃ ·t ₂ ·q ₂=0, C ₄ ² =t ₃ ·t ₂ ·t ₁ ·q ₁=0, C ₄ ³ =t ₃ ·t ₂ ·t ₁ ·t ₀ ·q ₀=0

The following table illustrates another example with A=1110 as the first binary number (line 1 in the following table), B=0101 as the second binary number (line 2) and z_(in)=1 as the incoming carry.

Index n 3 2 1 0 Z_(in) A 1 1 1 0 1 B 0 1 0 1 t_(n) = a_(n) ⊕ b_(n) 1 0 1 1 q_(n) = b_(n) ⊕ a_(n−1) 0 1 1 1 s_(n) ⁰ = a_(n) 0 0 0 1 C_(n) ⁰ = q_(n) 0 1 1 1 s_(n) ¹ = C_(n) ⁰ ⊕ s_(n) ⁰ 0 1 1 0 C_(n) ¹ = t_(n−1) · q_(n−1) 0 1 1 s_(n) ² = C_(n) ¹ ⊕ s_(n) ¹ 0 0 0 0 C_(n) ² = t_(n−1) · t_(n−2) · q_(n−2) 0 1 s_(n) ³ = C_(n) ² ⊕ s_(n) ² 0 1 0 0 C_(n) ³ = t_(n−1) · t_(n−2) · t_(n−3) · q_(n−3) 0 S = C_(n) ³ ⊕ s_(n) ³ 0 1 0 0

The initial estimation of the sum is here 0001 and the final expression is 0100. The corrections therefore had a positive effect. The emerging carry is here:

Z₄=a₃⊕C₄ ⁰⊕C₄ ¹⊕C₄ ²⊕C₄ ³=1

with

C ₄ ⁰ =t ₃ ·q ₃=0, C ₄ ¹ =t ₃ ·t ₂ ·q ₂=0, C ₄ ² =t ₃ ·t ₂ ·t ₁ ·q ₁=0, C ₄ ³ =t ₃ ·t ₂ ·t ₁ ·t ₀ ·q ₀=0

Reference is now made to FIG. 3, which illustrates an embodiment of the various modules of the adder according to the invention for implementing the method according to an embodiment of the invention.

In this example, the first calculation means MC1 comprises four pairs of “EXCLUSIVE OR” and “EXCLUSIVE OR complement” gates respectively NXOR1 and XOR1, NXOR2 and XOR2, NXOR3 and XOR3, NXOR4 and XOR4.

The first “EXCLUSIVE OR complement” gate NXOR1 receives as an input the input carry z_(in) and the first bit b_(o) of the second input binary number B, and delivers as an output the diagonal-generation signal q_(o), produced according to the formula defined above.

The logic gate XOR1 receives as an input the first bit b₀ of the second binary number B and the first bit a₀ of the first binary number A. The logic gate XOR1 delivers as an output the carry propagation signal t₀, produced according to the formula defined above.

Likewise the logic gate NXOR2 receives as an input the first bit a₀ of the first binary number A and the second bit b₁ of the second binary number B, and delivers as an output the diagonal-generation signal q₁.

The gate XOR2 receives as an input the second bit b₁ of the second binary number B and the second bit a₁ of the first binary number A, and delivers as an output the carry propagation signal t₁.

The logic gate NXOR3 receives as an input the second bit a₁ of the first binary number A and the third bit b₂ of the second input binary number, and delivers as an output the diagonal-generation signal q₂.

The logic gate XOR3 receives as an input the third bit b₂ of the second input binary number B and the third bit a₂ of the first binary number A, and delivers as an output the carry propagation signal t₂.

The logic gate NXOR4 receives as an input the third bit a₂ of the first binary number A and the fourth bit b₃ of the second binary number B.

The logic gate XOR4 receives as an input the last bit b₃ of the second binary number B and the last bit a₃ of the first binary number A, and delivers as an output the carry propagation signal t₃. All the outputs of the gates NXOR1, XOR1, . . . , NXOR4, XOR4 are connected to the input of the second calculation means MC2.

From the signals delivered by the first calculation means MC1, the second calculation means MC2 produces the various correction signals.

Given that the correction signal C₀ ⁰ is equal to the diagonal-generation signal q₀, this is directly delivered at the output of the second calculation means MC2 to the correction means mcorr1.

Likewise, given that the correction signal C₁ ⁰ is equal to the signal q₁, this is directly delivered at the output of the second calculation means MC2 to the correction means mcorr2.

In order to produce the correction signal C₁ ¹, the second calculation means MC2 comprises a logic “AND” gate AND1, which receives the signals q₀ and t₀ as an input and delivers C₁ ¹ as an output.

The signal q₂ is directly delivered at the output of the second calculation means MC2 to the correction means mcorr4, given that the signal c₂ ⁰ is equal to the signal q₂.

To produce the correction signal c₂ ¹, the second calculation means MC2 comprises a logic “AND” gate AND2, which receives the signals t₁ and q₁ as an input and delivers the signal C₂ ¹. Likewise, to produce the signal C₂ ², the second calculation means MC2 comprises a logic “AND” gate AND3, which receives the signals t₁, t₀ and q₀ as an input and delivers the signal C₂ ².

To produce the correction signal C₃ ⁰, the second calculation means delivers the signal q₃ directly as an output to the correction means mcorr7.

As for the preceding corrections signals, the correction signal C₃ ¹ is produced by means of a logic “AND” gate AND4, which receives the signal t₂ and the signal q₂ as an input. The correction signal C₃ ² is produced by means of a logic “AND” gate AND5, which receives the signals t₂, t₁ and q₁ as an input. The correction signal C₃ ³ is produced by means of a logic “AND” gate AND6, which receives the signals t₂, t₁, t₀ and q₀ as an input.

To produce the correction signals for the resulting carry z₄, the second calculation means MC2 comprises four logic “AND” gates AND7, AND8, AND9, AND10. The logic “AND” gate AND7 receives at the signals t₃ and q₃ as an input and delivers the signal c₄ ⁰ as an output. The second logic gate AND8 receives the signals t₃, t₂ and q₂ as an input and delivers the correction signal C₄ ¹ as an output.

The third logic gate AND9 receives the signals t₃, t₂, t₁ and q₁ as an input and delivers the correction signal C₄ ² as an output.

The last logic gate AND10 receives the signals t₃, t₂ t₁ and q₀ as an input and delivers the correction signal C₄ ³ as an output.

The estimation means MEST can be implemented by means of four switches respectively INV0, INV1, INV2 and INV3, which receive respectively as an input the bits a₀, a₁, a₂ and a₃ and deliver as an output the signals a₀, a₁, a₂ and a₃ to the correction means. In addition, the estimation means MEST delivers directly as an output the most significant bit a₃ of the first binary number A, for producing the resulting carry z₄.

All the connection means mcorr1, . . . mcorr14 are implemented by means of “EXCLUSIVE OR” gates.

The “EXCLUSIVE OR” gate implementing the correction means mcorr1 receives as an input the first estimation s_(o) of the first bit of the sum S and the correction signal C₀ ⁰, and delivers as an output the bit s₀.

The “EXCLUSIVE OR” gate mcorr2 receives as an input the first estimation S₁ of the second bit of the sum S and the correction signal C₁ ⁰ and delivers as an output an intermediate signal S₁ ¹ corresponding to a second estimation S₁ ¹ of the second bit of the sum S. The “EXCLUSIVE OR” logic gate mcorr3 receives as an input the signal S₁ ¹ and the correction signal C₁ ¹ and delivers as an output the second bit s₁ of the sum S.

The “EXCLUSIVE OR” gate mcorr4 receives as an input the first estimation S₂ ⁰ of the third bit of the sum S and the correction signal C₂ ⁰ and delivers the signal s₂ ¹ as an output. The “EXCLUSIVE OR” gate mcorr5 receives as an input this signal s₂ ¹ and the correction signal C₂ ¹, and delivers the signal s₂ ² as an output. The “EXCLUSIVE OR” gate mcorr6 receives as an input the signal s₂ ² and the correction signal C₂ ² and delivers the third bit s₂ as an output.

Likewise, the “EXCLUSIVE OR” gate mcorr7 receives as an input the first estimation S₃ ⁰ of the third bit of the sum S and the correction signal C₃ ⁰ and delivers the signal s₃ ¹ as an output. The “EXCLUSIVE OR” gate mcorr8 receives as an input this signal s₃ ¹ and the correction signal C₃ ¹ and delivers the correction signal s₃ ² as an output to an “EXCLUSIVE OR” gate constituting the correction means mcorr9. In addition, the “EXCLUSIVE OR” gate mcorr9 receives the correction signal c₃ ² as an input and delivers the signal S₃ ³ as an output. The “EXCLUSIVE OR” gate mcorr10 receives as an input the signal s₃ ³ and the correction signal C₃ ³ and delivers as an output the last bit S₂ of the sum S.

Likewise, for producing the resulting carry z₄, the correction means mcorr11 is implemented by an “EXCLUSIVE OR” gate that receives as an input the first estimation z₄ ⁰ of the carry z₄ and the correction signal c₄ ⁰ and delivers the signal z₄ ¹ as an output. The correction means mcorr12 comprises an “EXCLUSIVE OR” logic gate that receives as an input the signal z₄ ¹ and the correction signal C₄ ¹ and delivers the signal z₄ ² as an output to the correction means mcorr13. The means mcorr13 comprises an “EXCLUSIVE OR” logic gate that also receives the correction signal C₄ ² as an input and delivers the signal z₄ ³ as an output intended for the “EXCLUSIVE OR” logic gate implementing the connection means mcorr14. The means mcorr14 also receives the correction signal c₄ ³ as an input and delivers the resulting carry z₃₋₀ as an output.

Reference is now made to FIG. 4, which illustrates an integrated circuit comprising a system for making an addition with three binary numbers A, B and C.

The system SYS comprises a first adder ADD1 and a second adder ADD2. The first adder ADD1 receives as an input the first and second binary numbers respectively A and B and produces a sum A+B as an output.

The second adder ADD2 receives as an input the intermediate sum A+B as well as the third binary number C and produces a sum S corresponding to the sum of the three input binary numbers A, B and C.

For each additional binary number to be added, the system SYS comprises an additional adder.

Reference is now made to FIG. 5, which shows an adder on several levels or more precisely a 16-bit adder with group carry propagation.

This type of adder, produced conventionally, is well known to persons skilled in the art.

The 16-bit adder SYS comprises four adders A₁, A₂, A₃ and A₄ as described previously. More precisely, the adder A1 is shown in FIG. 6.

The second calculation means MC2 of the adder A1 comprises, in addition to the adder shown in FIG. 1, an additional output able to deliver a group propagation signal t₃₋₀. For this, the second calculation means MC2 comprises in this example an additional logic gate, here a logic “and” gate AND11, which receives as an input the signals t₀, t₁, t₂, and t₃.

The logic gate AND10 has then been modified and receives as an input the signals t₃, t₂, t₁, t₀ as well as the complementary of the first bit b₀ of the second input number B.

The bit b₀ is delivered by the first calculation means MC1, which for this embodiment comprises a switch INV4 that receives as an input the first bit b₀ of the second binary number B and delivers its complementary b₀ as an output.

Reference is made once again to FIG. 5. The first adder A1 receives as an input the signals b₀, a₀, . . . , b₃, a₃ and the input carry z_(in), and delivers as an output the first four bits of the resulting sum s₀, . . . s₃, the resulting carry z₄ as defined in FIG. 6, and the group propagation T₃₋₀ in the case of the adder A1. These signals are delivered to a group propagation module MPG, which receives as an input the resulting carry z₃₋₀ from the first adder A₁, the group propagation signal T₃₋₀ and the input carry z_(in). The group propagation module MPG produces a new carry z₄ defined by: z₄=z₃₋₀⊕T₃₋₀·z_(in).

Likewise, the adders A₂, A₃ and A₄ receive respectively the input signals b₄, a₄, . . . b₇, a₇ and b₈, a₈, . . . b₁₁, a₁₁ and b₁₂, a₁₂, . . . , b₁₅, a₁₅, as well as the resulting carries z₄, z₈ and z₁₂ produced by the propagation module MPG.

The adder A₂ delivers as an output the bits s₄, . . . s₇ of the sum S, the adder A3 delivers the output bits s₈, . . . , s₁₁ and the adder A₄ delivers the bits of the sum s₁₂, . . . , s₁₅.

The module MPG generates a resulting carry z₁₆ such that:

z ₁₆ =z ₁₅₋₁₂ ⊕T ₁₅₋₁₂ ·z ₁₁₋₈ ⊕T ₁₅₋₁₂ ·T ₁₁₋₈ ·z ₇₋₄ ⊕T ₁₅₋₁₂ ·T ₁₁₋₈ ·T ₇₋₄ ·z ₃₋₀ ⊕T ₁₅₋₁₂ ·T ₁₁₋₈ ·T ₇₋₄ ·z ₃₋₀ ⊕T ₁₅₋₁₂ ·T ₁₁₋₈ ·T ₇₋₄ ·T ₃₋₀ ·z _(in)

as well as a group propagation signal z_(g) such that:

z _(G) =z ₁₅₋₁₂ ⊕T ₁₅₋₁₂ ·z ₁₁₋₈ ⊕T ₁₅₋₁₂ ·T ₁₁₋₈ ·z ₇₋₄ ⊕T ₁₅₋₁₂ ·T ₁₁₋₈ ·T ₇₋₄ ·z ₃₋₀

and a group propagation signal t_(G) calculated according to the following expression:

T _(G) =T ₁₅₋₀ =T ₁₅₋₁₂ ·T ₁₁₋₈ ·T ₇₋₄ ·T ₃₋₀|

The signals z_(G) and T_(G) correspond respectively to the generation and group propagation signals of all the adders A1, . . . , A4.

FIG. 7 also depicts an adder with propagation of the carry by group receiving 64 bits as an input. This type of adder, well known to persons skilled in the art, can be used with the adders as described in FIG. 6 as well as two levels of group propagation modules.

The system SYS comprises a first level consisting of four group propagation modules MPG1, MPG2, MPG3 and MPG4. Each group propagation module is connected to four adders, respectively A1, . . . , A₄ and A₅, . . . , A₈ and A₉, . . . A₁₂ and A₁₃, . . . , A₁₆.

The second group propagation module level comprises a module MPG5 that receives as an input the output signals delivered by each group propagation module of the first level.

The adder as described above can be used in place of a conventional 64-bit adder, with group carry propagation in all configurations.

The present disclosure proposes a completely different implementation of an n-bit adder, able to be used in place of the standard adders in any configuration.

An aspect of the disclosure proposes an adder for reducing the number of vectors in the set of tests used to check the functioning of the logic gates that it comprises.

Although the present disclosure has been described with reference to one or more examples, workers skilled in the art will recognize that changes may be made in form and detail without departing from the scope of the disclosure and/or the appended claims. 

1. An n-bit adder of a first and second binary number, comprising: a first calculation means with 2n inputs for receiving the n values of bits of said first and second binary numbers and an additional input for receiving an input carry (z_(in)), said first calculation means being able to produce, from each of the n pairs of bit values of the same rank, a carry propagation signal (t_(n)), wherein the first calculation means is able furthermore to produce n diagonal-generation signals (q_(n)), each diagonal-generation signal being produced from the value of the bit of rank k of the second number, k varying between 0 and n−1, and the value of the bit of rank k−1 of the first number or of the input carry if said coefficient of rank k−1 does not exist, an estimation means able to perform a first estimation of each coefficient of the number resulting from the sum of the first and second numbers, taking the complementary of the value of the bit of corresponding rank of the first number, a second calculation means connected to the first calculation means and able to produce a set of correction signals from the propagation signals and diagonal-generation signals, and a correction block comprising n outputs and able to apply, to each estimated bit value of rank k of said sum, k+1 corrections by means of said correction signals, and to deliver as an output the n bits of the sum of the first and second numbers.
 2. Adder according to claim 1, in which the estimation means is furthermore able to perform a first estimation of a resulting carry (z₄) of said sum of the first and second numbers, from the most significant bit of the first number, in which the second calculation means is furthermore able to produce a set of supplementary signals correcting said resulting carry, from the propagation signals and diagonal-generation signals, and in which the correction block furthermore comprises an additional output for delivering said resulting carry, and is able to apply, to the estimated bit value of the resulting carry, k+1 corrections by means of said supplementary correction signals.
 3. Adder according to claim 1, in which the diagonal generation signal (q_(n)) of rank k is determined according to the following expression: q _(k)=( b _(k) ⊕a _(k-1) )| where: q_(k) is the diagonal-generation signal of rank k, b_(k) is the bit of rank k of the second binary number, a_(k-1) is the bit of rank k−1 of the first binary number.
 4. Adder according to claim 1, in which the p^(th) correction signal of the bit of rank k, with p varying between 0 and k, is determined according to the following expression: $\quad\begin{matrix} {C_{k}^{p} = {{q_{k}\mspace{11mu} {if}\mspace{14mu} p} = 0}} \\ {C_{k}^{p} = {{\left\lbrack {\prod\limits_{i = 1}^{p}t_{k - 1}} \right\rbrack \cdot q_{k - p}}^{{otherwise},}}} \end{matrix}$ where: C_(k) ^(p) is the p^(th) correction signal of the bit of rank k of the resulting sum, t_(i) is the carry propagation signal produced from the bits of rank i of the first and second binary numbers, q_(k) is the diagonal-generation signal of rank k.
 5. Adder according to claim 1, in which the bit of rank k of the resulting sum is determined according to the following expression: ${S_{k} = {\overset{\_}{a_{k}} \oplus {\sum\limits_{i = 0}^{k}\; C_{k}^{i}}}},$ where: s_(k) is the bit of rank k of the resulting sum, a_(k) is the bit of rank k of the first binary number, C_(k) ^(i) is the i^(th) correction signal of the bit of rank k of the resulting sum.
 6. Adder according to claim 1, in which the first calculation means comprises n pairs of “EXCLUSIVE OR” gates and “EXCLUSIVE OR complement” gates such that, for the k^(th) pair, the “EXCLUSIVE OR complement” gate is able to receive as an input the bit of rank k of the second binary number and the bit of rank k−1 of the first binary number or the input carry if said bit of the first binary number of rank k−1 does not exist, and able to deliver the corresponding diagonal-generation signal as an output, and such that, for said k^(th) pair, the “EXCLUSIVE OR” gate is able to receive the bits of rank k of the first and second binary numbers and is able to deliver the carry propagation signal of corresponding rank.
 7. Adder according to claim 1, in which the second calculation means comprises, for producing each correction signal of the bit of rank k, k “AND” gates, the i^(th) gate being able to produce a correction signal from the carry propagation and carry generation signals delivered as an input to said “AND” gates.
 8. Adder according to claim 1, in which the correction block comprises, for producing the bit of rank k of the resulting sum, k+1 “EXCLUSIVE OR” gates connected in series, each gate being able to: receive the estimated bit of rank k or the bit of rank k delivered by the “EXCLUSIVE OR” gate connected upstream, and a correction signal, perform a correction to the signal received as an input from said correction signal received.
 9. System for adding j bits, such that j is greater than 2, comprising j−1 adders according to claim 1 and connected in series, each adder being able to receive as an input a first binary number and a second binary number corresponding to the sum of two other binary numbers, which is delivered by the adder connected upstream in the series.
 10. System for adding j bits, such that j is greater than 2, comprising a set of adders according to claim 1 connected in parallel, in which said second calculation means of each adder: furthermore comprises an output able to deliver a group propagation signal (t_(n)) corresponding to the product of all the carry propagation signals (q_(n)), produced by said first calculation means, is able to produce said set of supplementary signals for correcting said resulting carry, from the propagation signals (t_(n)) and the diagonal-generation signals (q_(n)), as well as the complementary signal of the first bit of the second input binary number, the system furthermore comprising at least one group propagation module connected to all the adders and able to receive said resulting carry and said group propagation signal (t_(n)) produced by each adder and to produce firstly the input carry of an adder from the resulting carry and the group propagation signal of the previous adder, and secondly a new resulting carry and a new group propagation signal from the resulting carries and group propagation signals of all the adders.
 11. System according to claim 10, comprising a first set of propagation modules connected in parallel to the outlet of the adders, and another propagation module connected to the output of the said first set of propagation modules, able to receive the new resulting carry and the new group propagation signal of each propagation module of said first set, and able to produce, from each new resulting carry and each new group propagation signal, a new output carry and a new output group propagation signal.
 12. Method of adding a first and second n-bit binary number, comprising: a phase of receiving n bit values of the said first and second binary numbers and an input carry (z_(in)), a first calculation phase comprising production, from each of the n pairs of values of bits of the same rank, of a carry propagation signal (t_(n)), wherein the first calculation phase furthermore comprises the production of n diagonal-generation signals (q_(n)), each diagonal generation signal (q_(n)) being produced from the value of the bit of rank k of the second number, k varying between 0 and n−1, and the value of the bit of rank k−1 of the first number or of the carry if said coefficient of rank k−1 does not exist, a phase of estimating each coefficient of the number resulting from the sum of the first and second numbers, taking the complementary of the value of the bit of corresponding rank of the first number, a second calculation phase comprising production of a set of correction signals from the propagation signals and diagonal-generation signals, a correction phase comprising application, to each estimated bit value of rank k of said sum, of k+1 corrections using said correction signals, and delivery as an output of the n bits of the sum of the first and second numbers.
 13. Method according to claim 12, in which the estimation phase furthermore comprises a first estimation of a resulting carry (z₄) of said sum of the first and second numbers, from the last bit of the first number, in which the second calculation phase furthermore comprises production of set of supplementary signals for correction of said resulting carry, from the propagation signals (t_(n)) and diagonal-generation signals (qn), and in which the correction phase furthermore comprises delivery of the said resulting carry, and application, to the estimated bit value of the resulting carry, of k+1 corrections using said supplementary correction signals.
 14. Method according to claim 12, in which the diagonal-generation signal of rank k (q_(k)) is determined according to the following expression: q _(k)=( b _(k) ⊕a _(k-1) )| where: q_(k) is the diagonal-generation signal of rank k, b_(k) is the bit of rank k of the second binary number, a_(k-1) is the bit of rank k−1 of the first binary number.
 15. Method according to claim 12, in which the p^(th) correction signal of the bit of rank k, with p varying between 0 and k, is determined according to the following expression: $\quad\begin{matrix} {C_{k}^{p} = {{q_{k}\mspace{11mu} {if}\mspace{14mu} p} = 0}} \\ {C_{k}^{p} = {{\left\lbrack {\prod\limits_{i = 1}^{p}t_{k - 1}} \right\rbrack \cdot q_{k - p}}^{{otherwise},}}} \end{matrix}$ where: C_(k) ^(p) is the p^(th) correction signal of the bit of rank k of the resulting sum, t_(i) is the carry propagation signal produced from the bits of rank i of the first and second binary numbers, q_(k) is the diagonal-generation signal of rank k.
 16. Method according to claim 12, in which the bit of rank k of the resulting sum is determined according to the following expression: $S_{k} = {\overset{\_}{a_{k}} \oplus {\sum\limits_{i = 0}^{k}\; C_{k}^{i}}}$ where: s_(k) is the bit of rank k of the resulting sum, a_(k) is the bit of rank k of the first binary number, C_(k) ^(i) is the i^(th) correction signal of the bit of rank k of the resulting sum.
 17. Method according to claim 12, in which the first calculation phase comprises n pairs of “EXCLUSIVE OR” and “EXCLUSIVE OR complement” operations such that, for the k^(th) pair of operations, the “EXCLUSIVE OR complement” operation comprises reception as an input of the bit of rank k of the second binary number and of the bit of rank k−1 of the first binary number or of the carry if said bit of rank k−1 of the first binary number does not exist, and comprises delivery as an output of the corresponding diagonal-generation signal, and such that, for said k^(th) pair of operations, the “EXCLUSIVE OR” operation comprises reception of the bits of rank k of the first and second binary numbers and delivery of the carry propagation signal of corresponding rank.
 18. Method according to claim 12, in which the second calculation phase comprises, for producing each correction signal of the bit of rank k, k “AND” operations, the i^(th) operation comprising production of a correction signal from the carry propagation and carry generation signals.
 19. Method according to claim 12, in which the correction phase comprises, for production of the bit of rank k of the resulting sum, k+1 “EXCLUSIVE OR” operations in series, comprising reception of the estimated bit of rank k or of the bit of rank k processed during the preceding “EXCLUSIVE OR” operation of the correction phase, and a correction signal, each “EXCLUSIVE OR” operation comprising correction of the signal received as an input, from said correction signal. 